Cardiolipin biosynthesis and remodeling enzymes are altered during development of heart failure

Cardiolipin (CL) is responsible for modulation of activities of various enzymes involved in oxidative phosphorylation. Although energy production decreases in heart failure (HF), regulation of cardiolipin during HF development is unknown. Enzymes involved in cardiac cardiolipin synthesis and remodeling were studied in spontaneously hypertensive HF (SHHF) rats, explanted hearts from human HF patients, and nonfailing Sprague Dawley (SD) rats. The biosynthetic enzymes cytidinediphosphatediacylglycerol synthetase (CDS), phosphatidylglycerolphosphate synthase (PGPS) and cardiolipin synthase (CLS) were investigated. Mitochondrial CDS activity and CDS-1 mRNA increased in HF whereas CDS-2 mRNA in SHHF and humans, not in SD rats, decreased. PGPS activity, but not mRNA, increased in SHHF. CLS activity and mRNA decreased in SHHF, but mRNA was not significantly altered in humans. Cardiolipin remodeling enzymes, monolysocardiolipin acyltransferase (MLCL AT) and tafazzin, showed variable changes during HF. MLCL AT activity increased in SHHF. Tafazzin mRNA decreased in SHHF and human HF, but not in SD rats. The gene expression of acyl-CoA: lysocardiolipin acyltransferase-1, an endoplasmic reticulum MLCL AT, remained unaltered in SHHF rats. The results provide mechanisms whereby both cardiolipin biosynthesis and remodeling are altered during HF. Increases in CDS-1, PGPS, and MLCL AT suggest compensatory mechanisms during the development of HF. Human and SD data imply that similar trends may occur in human HF, but not during nonpathological aging, consistent with previous cardiolipin studies.     

Form of inorganic carbon involved as a product and as an inhibitor of c(4) Acid decarboxylases operating in c(4) photosynthesis

These studies demonstrated that CO₂ rather than HCO₃⁻ is the inorganic carbon metabolite produced by the C₄ acid decarboxylases involved in C₄ photosynthesis (chloroplast located NADP malic enzyme, mitochondrial NAD malic enzyme, and cytosolic phosphoenolpyruvate [PEP] carboxykinase). The effect of varying CO₂ or HCO₃⁻ as a substrate for the carboxylation reaction catalyzed by these enzymes or as inhibitors of the decarboxylation reaction was also determined. The K_mCO₂ was 1.1 millimolar for NADP malic enzyme and 2.5 millimolar for PEP carboxykinase. For these two enzymes the velocity in the carboxylating direction was substantially less than for the decarboxylating direction even with CO₂ concentrations at the upper end of the range of expected cellular levels. Activity of NAD malic enzyme in the carboxylating direction was undetectable. The decarboxylation reaction of all three enzymes was inhibited by added HCO₃⁻. For NADP malic enzyme CO₂ was shown to be the inhibitory species but PEP carboxykinase and NAD malic enzyme were apparently inhibited about equally by CO₂ and HCO₃⁻.     

Development of a dedicated two-dimensional gel electrophoresis system that provides optimal pattern reproducibility and polypeptide resolution.

The development of a dedicated two-dimensional gel electrophoresis system is described that provides superior performance in terms of high resolving power and enhanced gel-to-gel reproducibility. Isoelectric focusing is performed in a 1-mm capillary tube with a 0.08-mm thread, optimized for this application, incorporated along its length prior to polymerization of the gel matrix. The isoelectric focusing gel is 4% T, 2.6% C to minimize sieving of proteins and promote adhesion of the gel to the thread. The thread incorporated in the isoelectric focusing matrix prevents gel stretching and breakage during its application to the second dimension. An optimum ampholyte pH range has been defined based on 1600 polypeptides present in a transformed fibroblast cell lysate and verified using a variety of other cell types. The length of time required to complete an electrophoretic separation in the second dimension was found to depend on buffer conductivity establishing the importance of high quality electrophoresis grade reagents devoid of contaminating salts. To ensure reproducibility of electrophoretic separations, it is critical to maintain a strict control of temperature during the second dimension separation. This prevents altered migration of some polypeptides relative to neighboring polypeptides that have constant Rfs over a broad temperature range. It was also determined that to obtain the maximum information from a complex protein mixture it is critical to use a large format 22- x 22-cm two-dimensional electrophoretic system. Using the optimized two-dimensional electrophoretic system and computerized gel analysis, it was determined that molecular weight estimates of polypeptides differed by approximately 350 daltons between gels, while isoelectric point estimates differed by approximately 0.03 pH units between gels. Using the two-dimensional electrophoresis system described, approximately 1000 polypeptides can be routinely detected from silver-stained 10% polyacrylamide gels or 1600 polypeptides from autoradiographs of 35S-methionine-labeled polypeptides.     

Effect of amino acids on choline uptake and phosphatidylcholine biosynthesis in the isolated hamster heart

Choline uptake by the hamster heart has been shown to be enhanced by exogenous glycine. In this study, the effect of neutral, basic, and acidic amino acids on choline uptake was assessed. Hamster hearts were perfused with labelled choline, and in the presence of L-alanine, L-serine, or L-phenylalanine (greater than or equal to 0.1 mM), choline uptake was enhanced 20-38%. L-Arginine, L-lysine, L-aspartate, and L-glutamate did not influence choline uptake. The rate of phosphatidylcholine biosynthesis was unaffected by all amino acids tested. Enhancement of choline uptake by neutral amino acids was not additive or dose dependent but required a concentration threshold. The enhancement of choline uptake by neutral amino acids was not influenced by preperfusion with the same amino acid. Exogenous choline had no effect on the uptake of amino acids. We postulate that choline and the neutral amino acids are not cotransported and modulation of choline uptake is facilitated by direct interaction of the neutral amino acids with the choline transport system.     

The proton pore in the Escherichia coli F0F1-ATPase: substitution of glutamate by glutamine at position 219 of the alpha-subunit prevents F0-mediated proton permeability

Three mutations in the uncB gene encoding the a-subunit of the F0 portion of the F0F1-ATPase of Escherichia coli were produced by site-directed mutagenesis. These mutations directed the substitution of Glu-219 by Gln, or of Lys-203 by Ile, or of Glu-196 by Ala. Strains carrying either the Lys-203 or Glu-196 substitutions showed growth characteristics indistinguishable from the coupled control strain. Properties of membrane preparations from these strains were also similar to those from the coupled control strain. The substitution of Glu-219 by Gln resulted in a strain which was unable to utilise succinate as sole carbon source and had a growth-yield characteristic of an uncoupled strain. Membrane preparations of the Glu-219 mutant were proton impermeable and the F1-ATPase activity was inhibited by about 50% when membrane-bound. The results are discussed with reference to a previously proposed intramembranous proton pore involving subunits a and c.     

Regulation of NADP-malate dehydrogenase in C4 plants: relationship among enzyme activity, NADPH to NADP ratios, and thioredoxin redox states in intact maize mesophyll chloroplasts

NADP-malate dehydrogenase activity, the ratio of NADPH to NADP, and thioredoxin redox state in Zea mays chloroplasts were determined after various treatments. Following transfer from dark to light, NADP-malate dehydrogenase was activated more than 20-fold within 10 min while the proportion of pyridine nucleotide as NADPH increased from about 25 to 90%, and the proportion of thioredoxin in the reduced form increased from 20 to more than 90%, in less than 1 min. After transfer back to the dark, NADPH levels dropped very rapidly to the initial values recorded before illumination, while enzyme activity and reduced thioredoxin levels decreased more slowly. Addition of oxaloacetate or 3-phosphoglycerate to illuminated chloroplasts results in a decrease of about 70% in the activity of NADP-malate dehydrogenase, a 30% decrease in the level of NADPH, and a 25% decrease in the reduced thioredoxin content. Adding dihydroxyacetone phosphate and pyruvate had no effect. These results are considered in relation to the hypothesis that NADP-malate dehydrogenase activity in chloroplasts may be determined by factors regulating the ratio of NADPH to NADP as well as those influencing the redox state of thioredoxin.     

Regulation of NADP-malate dehydrogenase in C4 plants: effect of varying NADPH to NADP ratios and thioredoxin redox state on enzyme activity in reconstituted systems

Activation and inactivation of NADP-malate dehydrogenase purified from Zea mays leaves were followed in a reconstituted system provided with thioredoxin poised in various redox states with dithiothreitol. The initial rate of activation or inactivation of NADP-malate dehydrogenase was proportional to the concentration of reduced or oxidized thioredoxin, respectively. The rate of inactivation was about 16 times that for activation at pH 7.4. Both activities increased when the pH was increased from 7.4 to 8.0. The redox potentials (E'0, pH 7) for the dithiol-disulfide systems of thioredoxin and NADP-malate dehydrogenase were estimated to be about -0.30 and -0.33 V, respectively. As would be predicted from these values, high proportions of active malate dehydrogenase were developed only in the presence of very high ratios of reduced to oxidized thioredoxin. Similarly, when pyridine nucleotide was included, a high degree of activation of malate dehydrogenase was only observed with high NADPH/NADP ratios. These results confirm predictions based on models developed in earlier studies that the NADPH to NADP ratio as well as the thioredoxin redox state may be critical in determining the level of NADPH-malate dehydrogenase activity in vivo.